機(jī)械外文翻譯--超聲波加工過程
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1、附 錄Ⅰ Micro removal of ceramic material (Al2O3) in the precision — Ultrasonic machining Abstract Ultrasonic machining process is an efficient and economical means of precision machining of ceramic materials. However, the mechanics of the process with respect to crack initiation and propagatio
2、n, and stress development in the ceramic workpiece subsurface are still not well understood. This article presents experimental simulation of the process mechanics in an attempt to analyze the material removal mechanism in machining of ceramic (Al2O3). It is found that low-impact force causes only s
3、tructural disintegration and particle dislocation. The high-impact force contributes to cone cracks and subsequent crater damage. ? 1999 Elsevier Science Inc. All rights reserved. Keywords: Ceramic material (Al2O3); Utrasonic machining 1. Introduction Advanced engineering ceramics plays an increa
4、singly important role in the modern manufacturing industries, especially in aerospace, automotive, electronics, and cutting tool industries because of its superior properties such as chemical inertness, high strength and high stiffness at elevated temperatures, high strength to weight ratio, high ha
5、rdness, corrosion resistance, and oxidation resistance [1]. The main barrier hindering further application of advanced ceramics is the inability of the present manufacturing processes to economically and efficiently machine (especially precision machine) ceramics. Currently, grinding is one of the
6、most commonly used processes in the precision machining of ceramic, however,its high energy consumption results in high machining cost. Moreover, grinding also causes workpiece surface damage[2]. Laser beam machining (LBM) has the potential to be aviable alternative for ceramic machining, but surfac
7、e quality of machined parts is relatively poor [3]. Electrical discharge machining (EDM) is another alternative for ceramic machining,and many engine parts have been successfully machined by EDM [4]. Unfortunately, EDM can machine only electrically conductive materials. Other methods such as electro
8、n-beam and ion-beam cutting, and microwave cutting have also been proposed, but require additional research and development efforts [5–7]. Ultrasonic machining (USM), offers an effective alternative for precision machining of ceramics due to its many unique characteristics [8,9]. Unlike EDM, wire-E
9、DM or electro-chemical machining (ECM), which are all suited only for machining electrically conductive materials, USM can machine all hard and brittle materials [10].Furthermore, USM does not cause any thermal or chemical alterations in the subsurface characteristics of the machined material. Such
10、alterations are inevitable in EDM, ECM, wire-EDM, LBM and many traditional machining. Additionally, USM also produces a better precision surface finish compared to other material removal processes. In most USM practices, an average workpiece surface finish of 0.50 mm can be obtained. With appropriat
11、e measures, a surface finish of 0.25 mm can also be achieved [11]. USM has a great potential for applications in precision machining of ceramics, however, the material removal mechanism especially with respect to the microstructure and properties of the work material is not well understood [12]. T
12、he stresses developed in the subsurface are of critical importance when machining brittle ceramics as the inherent microstructural variations and subsurface flaw characteristics influence the resultant stress distributions in the subsurface [13,14]. It is necessary to Corresponding author investig
13、ate and understand the micro-material removal mechanism in ultrasonic mechanism for improving its efficiency and precision in machining of ceramics. In USM, the tool strikes the workpiece about 20,000 times in a second, a machining action occurs as the tool vibrates the fine abrasive particles flo
14、wing through a very small gap (ten to hundred microns) and propels them against the workpiece material. Material removal takes place in the presence of abrasive slurry. Therefore, it is very difficult to monitor directly or indirectly the presence and progress of involved physical processes. One of
15、the alternatives is to experimentally simulate the conditions of each physical processes to study their respective contribution. This article presents the results of experiments conducted to simulate the kinematics of the impact mechanism similar to the actual ultrasonic machining process. An impact
16、 test system was designed to simulate the impact mechanics of single diamond grit impelled by the contact force of the vibrating tool to strike an Al2O3 workpiece. The impact results on Al2O3 are analyzed. The experimental set-up and parameter selection for the impact test are described in second se
17、ction. The experimental results are given in third section. The microstructural analysis for understanding crack propagation and surface fracture is Presented in fourth section. The last section summarizes the conclusions of this study. 2. System set-up for the impact test The testing unit (Fig.
18、1a) in the experiments consists of three rigid tubular rods bolted to a solid mild steel base, and clamped to a triangular plate at the top. The length of these rods which determine the maximum drop heights are 3 m. An “N” Brale diamond tipped hardness tester (Wilson Instruments, PA) is used to si
19、mulate a single abrasive particle. Once the tool assembly, comprising of the diamond tip fitted to a plexiglas frame (Fig. 1b), is positioned at the predetermined drop height, an electromagnetic release mechanism which also activates a trigger device controlling the start of the time measurements re
20、leases the indenter. This setup permits the indenter assembly to accelerate due to gravity without any disturbances or delays. The tool head provides a base for a unidirectional ENTRAN-EGB 125 accelerometer, which is a small-sized low-weight device capable of measuring accelerations up to 5000 g. Si
21、gnals transmitted by a miniature semiconductive wheatstone bridge of the accelerometer device are amplified by a storage oscilloscope, and the data is stored in a 386 PC connected to the data acquisition system. Because the impact force is a function of the mass of the indenter, the weight of the to
22、ol assembly was designed for this test. 2.1. Experimental parameter selection In most cases for an USM machining, the diameter of a vibrating tool ranges from 4 to 6 mm. The size of the abrasive particles are between 50 and 75 mm. In practice forces applied in ultrasonic machining are within a ran
23、ge of 4.0 and 6.0 N [11]. Approximately, 100 particles are assumed to be covered under the tool during each down strike, and the mass of the indenter assembly is estimated by Newton’s second law of motion, Mass (M) 5 0.51 (kg)/ 9.806(m/s2) 5 52.0 g. To simulate the effect of a particle striking on a
24、 workpiece surface in an USM machining process, a lightweight plexiglas frame was designed to hold the indenter assembly. The assembly with total weight of 50.0 g drops from a precalculated height to strike the workpiece. The drop heights for the indenter are between 45–250 cm to obtain the impact v
25、elocities observed during the actual USM processes. A set of five drop heights were used in this experiment and a time device is automatically triggered when the indenter is released from its predetermined drop position. Fine grained (5 mm) Alumina (Kadco Ceramics, NJ) is impacted at two locations
26、under predetermined impact velocities; the impact locations are far apart to avoid any interaction effects. The diameter of the indenter tip is selected close to the size of particles used in USM machining. The test is aimed at analyzing the dynamic parameters of a single particle during impact and
27、 the fracture characteristics of the damage. The impact parameters are calculated based on free fall up to the point of impact and the characteristics during contact are estimated either directly from measurements or indirectly from calculations. When graphically represented over time, the character
28、istics of a single particle during impact are illustrated by different parameters such as force, velocity, or distance. An understanding of the mechanics of the material removal process based on observations of the microstructure were performed with the aid of a high resolution scanning electron mic
29、roscope. Fig. 2. a) Impact force and velocity over time; b) Impact force and depth over time; c) Impact velocity and depth over time. 3. Results: Impact force, velocity, and penetration depth The output from the accelerometer and the time measurements provide specific impact characteristics such
30、as the force exerted, the impact velocity, and the depth of penetration. The results of the different impact characteristics, are presented in Table 1. The impacts are identified by the workpiece number (p01, p02, and p03), and the impact number (i01, . . . i05). The maximum points sampled indicate
31、the number of data points collected at a sampling rate of a million points per second. Relative time values are computed with the aid of computer software, which identifies the peak position and triggers a relative time clock to store data up to 500 points before the maximum depth (peak) and up to 6
32、000 points after the peak. The end time in seconds is the instant when the indenter leaves the workpiece surface after impact. Fig. 2 (a, b, and c) represent the comparative results of the impact parameters of force, velocity, and depth of penetration at a drop velocity of 1.92 m/sec. Fig. 2a comp
33、ares the impact velocity and force during penetration; at the point of contact the velocity is maximum, and as the acceleration at this point is zero, the impact force drops to zero. The velocity reduces on impact and finally reaches zero at a point when the indenter is momentarily stationery, this
34、point corresponds to the instant when the force exerted on the indenter by the material is maximum. This instant is also described by the maximum depth of penetration as described in Fig. 2b and c. The velocity on rebound increases as described by the curve until a combination of the acceleration du
35、e to gravity and material resistance reduces it to zero. A summary of results of the impact characteristics are presented in Table 2. For linearly increasing values of the maximum free fall velocity there is a proportional increase in the maximum force experienced by the diamond tip during impact,
36、and a corresponding increase in the penetration depth. Fig. 3 describes the effect of the maximum free fall velocity on the penetration depth. The depth shows a steep increase at intermediate velocities and a relatively gradual increase at the low and high velocities. Fig. 3. Effect of maximum free
37、fall velocity on penetration depth. Fig. 4. Schematic of the crack morphology in brittle materials [15]. Fig. 5. Surface characteristics at an impact velocity of 0.98 m/sec. (3 750.) 4. Microstructure analysis As the crack propagation and subsurface fractures are mainly responsible for material re
38、moval, the SEM technique is particularly useful in its ability to give a vivid and more definitive representation of the crack types and their modes of propagation with respect to the microstructural characteristics of the material. In a study reported by Smith et al. [15] on indentation fractures
39、in brittle materials, median cracks growing perpendicular to the surface just below the tip of the indenter and are contained within the subsurface, but eventually propagate to the surface. Lateral cracks grow parallel to the impact surface, and propagate toward the top at high-impact velocities. T
40、he characteristics of these cracks are described schematically in Fig. 4, which shows a sectional view of the impacted area. The SEM micrographs of the damaged area at different impact velocities are presented in Fig. 5–9. Fig. 5 shows the surface characteristics at 7503, of the damage under an imp
41、act velocity of 0.98m/sec. It can be seen that fragmentation, chipping, and microfracture due to the impact force have mainly contributed toward material removal. Some material removal may also have resulted from dislodged particles as observed by the presence of cavities in the microstructure. With
42、 an impact velocity of 1.15m/sec., the presence of intergranular microcracks can be observed in Fig. 6. However, most of the material is removed from the impact force. At an impact velocity of 1.5 m/sec., cracks projecting from the deformation zone are clearly visible in Fig. 7. The presence of thes
43、e cracks indicate lateral and median crack propagation to the surface. The presence of intergranular microcracks are also visible and are indicated by arrowheads. Because material removal involves both plastic flow and fracture, a combination of compressive and tensile stresses, respectively, are r
44、esponsible for material removal [11]. Median cracks perpendicular to the surface and propagating below the deformation zone, result from the compressive stresses due to the impact force of the indenter. Lateral Fig. 6. Surface characteristics under an impact velocity of 1.15 m/sec. (3350.) Fig. 7. S
45、urface characteristics under an impact velocity of 1.5 m/sec. (3650.) Fig. 8. Surface characteristics under an impact velocity of 1.9 m/sec.(31200.) Fig. 9. Surface characteristics from an impact velocity of 2.05 m/sec. (3750.)cracks propagate to the surface due to high impact forces [15] and merge
46、with the median cracks (Fig. 8) describes the deformation zone with cracks propagating from the epicenterat an impact velocity of 1.5 m/sec.. These cracks originate in the subsurface and propagate to the top, contributing to material removal by dislodging large sections of the material. The network
47、of intergranular microcracks also contribute to the material removal process. Fig. 9 describes the surface characteristics of the damage under an impact velocity of 2.05 m/sec. The dislodged particles in the crater range from small grain sized particles to chunks of dislodged material in the 40–50 m
48、m. range. In an effort to relate the surface area of the damage to the impact velocity, a measurement technique was applied to estimate the area of each crater. The results of the test shown in Fig. 10 describes an increasing trend for increasing impact velocities. This may be attributed to the ma
49、terial removed when lateral and median cracks merge at the surface. Thus, the impact zone material removal occurs mainly from a combination of particle coalescence and microstructural disintegration. Below the plastic zone, at the lowimpact forces, material removal occurs from particles dislodged fr
50、om the surface. Fragmentation from the impact force of the diamond tip, and intergranular microcracks also result in material removal. At the higher impact velocities between 1.92 and 2.1 m/sec lateral and median cracks merge at the surface to dislodge large particles of material in the range betwee
51、n 20 to 50mm. At these loads the network of intergranular microcracks also play a significant role in the material removal process. 5. Conclusions This study was aimed at understanding the mechanism of the material removal process in fine grain Alumina during precision ultrasonic machining. Micro
52、structural analysis of the damaged surface due to the dynamic impact of an abrasive particle indicates the presence of two phenomena that contribute to material removal; the deformation at the point of impact, and the brittle structure below the impact zone. From the dynamic impact tests, material r
53、emoval in the USM process appears to be a function of the impact velocity, which is determined by the frequency and amplitude of the vibrating tool. Material in the impact zone is removed by fragmentation and by chipping microfracture due to the high compressive stresses developed in the region. At
54、low-impact velocities, material removal in the brittle substructure occurs mainly due to structural disintegrations and particle dislocations. At higher velocities, material is removed by a network of intergranular microcracks and from the propagation of lateral and median cracks. These cracks merge
55、 at the surface dislodging large sections of the material. Acknowledgments The authors thank the Nebraska Research Initiative Fund for their financial support. The authors also gratefully acknowledge the assistance of Ms. L. Shi and Mr. N. Saxena in the preparation of this article.
56、 附 錄Ⅱ 超聲波加工過程是一個(gè)高效和經(jīng)濟(jì)的手段,用在精密加工的陶瓷材料上。然而,力學(xué)這一過程對(duì)裂紋產(chǎn)生和擴(kuò)大,并強(qiáng)調(diào)發(fā)展陶瓷工件表層仍然沒有得到很好的理解。本文介紹的模擬實(shí)驗(yàn)研究的過程力學(xué),試圖分析材料去除機(jī)理在加工陶瓷(氧化鋁)過程中。結(jié)果發(fā)現(xiàn),低沖擊力只有助于結(jié)構(gòu)性解體和粒子脫位。高沖擊力有助于錐裂縫和隨后的縫口損壞。 關(guān)鍵詞:陶瓷材料(氧化鋁) ;超聲波加工 1 :導(dǎo)言 先進(jìn)的工程陶瓷發(fā)揮著越來越重要的作用,現(xiàn)代制造業(yè),特別是在航空航天,汽車,電子和切割工具行業(yè),由于其優(yōu)越的性能,如化學(xué)惰性,高強(qiáng)度,高剛度在較高高溫,高強(qiáng)度重量比,
57、硬度高,耐腐蝕,抗氧化 目前,磨削是一種最常用的精密加工陶瓷方法,然而,其能源消耗高,結(jié)果增加加工費(fèi)用。此外,還造成磨削工件表面損傷 。激光加工( LBM )有可能成為可行的選擇陶瓷加工,但表面質(zhì)量機(jī)械零件的相對(duì)較差 。放電加工是另一個(gè)替代的陶瓷加工,許多發(fā)動(dòng)機(jī)部件已成功應(yīng)用電火花加工 。然而,電火花加工機(jī)只能用唯一導(dǎo)電材料。其他方法,例如電子束和離子束切割和微波切割也被提出,但需要額外的研究和開發(fā)工作。 超聲波加工(超聲波馬達(dá)) ,提供了一個(gè)有效的用于精密加工陶瓷的方法由于其有許多獨(dú)特的特點(diǎn)。電火花,線切割或電化學(xué)加工 ,這些都是只適合加工導(dǎo)電材料,超聲波馬達(dá)可用于所有硬脆材料
58、 。此外,超聲波加工會(huì)引起加工材料的任何熱或化學(xué)的表層特征改變。這種改變?cè)陔娀鸹庸?,電子?duì)抗,線切割,LBM和許多傳統(tǒng)的機(jī)械加工中是不可避免的。此外,超聲波加工作了一個(gè)更好的表面加工精度與其他材料去除過程相比。在大多數(shù)超聲波加工法中,平均工件表面光潔度可達(dá)0.50毫米。有了適當(dāng)?shù)拇胧?,表面光潔度也可以?shí)現(xiàn)到0.25毫米 。 超聲波加工大的應(yīng)用潛力在精密加工陶瓷中,然而,對(duì)材料去除率機(jī)制,尤其是對(duì)微觀結(jié)構(gòu)和工作性質(zhì)的材料沒有得到很好的理解。在強(qiáng)調(diào)發(fā)達(dá)國家在地下關(guān)于要性脆性陶瓷加工時(shí)的固有微觀結(jié)構(gòu)的變化和地下缺陷特征由此造成的影響應(yīng)力分布在地下微觀材料去除機(jī)理的超聲機(jī)制為提高其效率和加工精度陶
59、瓷。 在超聲波加工中,罷工工件約20000次每秒,發(fā)生運(yùn)動(dòng)的工具振動(dòng)細(xì)磨料顆粒流經(jīng)一個(gè)非常小的差距( 10至100微米) ,并推動(dòng)他們到工件材料。材料去除發(fā)生在在場(chǎng)的磨料泥漿。因此,它是非常困難的監(jiān)測(cè)直接或間接的存在和進(jìn)步涉及的物理過程。一個(gè)替代辦法是模擬實(shí)驗(yàn)條件的每個(gè)物理過程,研究其各自的貢獻(xiàn)。本文介紹的實(shí)驗(yàn)結(jié)果進(jìn)行運(yùn)動(dòng)學(xué)模擬的影響類似機(jī)制的實(shí)際超聲波加工過程。撞擊試驗(yàn)系統(tǒng)的設(shè)計(jì)是為了模擬影響力學(xué)單鉆石的砂礫促使接觸力的振動(dòng)工具罷工的氧化鋁工件。 結(jié)果影響氧化鋁進(jìn)行的分析。實(shí)驗(yàn)設(shè)置和參數(shù)的選擇影響試驗(yàn)中描述的第二部分。實(shí)驗(yàn)結(jié)果給出了第三節(jié)的微觀結(jié)構(gòu)分析理解和表面裂紋擴(kuò)展第四部分中提出的。最
60、后一節(jié)總結(jié)了這項(xiàng)研究的結(jié)論。 2 。系統(tǒng)設(shè)置的影響試驗(yàn) 測(cè)試單位(圖1A )在實(shí)驗(yàn)中包括三個(gè)剛性管桿螺栓,以堅(jiān)實(shí)的鋼架為基礎(chǔ),鉗位到三角形板在頂部。這些長度棒確定的最大下降高度為3米 圖 1 。 表1 結(jié)果所產(chǎn)生的影響在不同的特性下降高地測(cè)試 圖 a為壓降測(cè)試 圖 b為影響的立場(chǎng) “ N ”形狀鉆石刀具的硬度儀(威爾遜儀器巴勒斯坦權(quán)力機(jī)構(gòu))用在模擬磨粒。當(dāng)?shù)毒弑话惭b上,組合的鉆石刀具安裝上有機(jī)玻璃框架(圖1B) ,在預(yù)定下降高度上定位,電磁釋放裝置激活觸發(fā)裝置來控制開始測(cè)量時(shí)刻的壓頭。此安裝允許,由于加速重力沒有任何干擾或延誤。該工具頭提供了一個(gè)基地,單向進(jìn)
61、入 ,安裝裝置加速度125,這是一個(gè)小型體重裝置能測(cè)量加速度高達(dá)5000克信號(hào)轉(zhuǎn)交的一個(gè)縮影半導(dǎo)體壓阻橋梁的加速度裝置擴(kuò)增存儲(chǔ)示波器,數(shù)據(jù)存儲(chǔ)在一個(gè)相當(dāng)于386個(gè)人腦的電腦數(shù)據(jù)采集系統(tǒng)中。由于沖擊力影響是一個(gè)功能的質(zhì)量壓痕,這一試驗(yàn)的目的是為重量工具安裝。 2.1 實(shí)驗(yàn)參數(shù)的選擇 在大多數(shù)情況下的超聲波馬達(dá)加工,直徑振動(dòng)工具范圍從4至6毫米。磨料顆粒尺寸的大小是50至75毫米。在實(shí)踐中其適用于超聲波加工的范圍為4.0和6.0 大約100顆粒子被假定以所涵蓋的工具在每次下跌受塤,和大眾的壓痕一起估計(jì), 牛頓第二定律的運(yùn)動(dòng),質(zhì)量(男) 5 0.51 (公斤) / 9.806 ( m
62、/s2 ) 5 52.0克 模擬粒子效果顯著的工件表面加工工藝的超聲波馬達(dá),輕巧有機(jī)玻璃框架的目的是要舉行壓大會(huì)大會(huì)的總重量五十○點(diǎn)○克下降了 precalculated高度罷工工件。下拉高地壓為45-250厘米之間取得觀察速度的影響在實(shí)際超聲波馬達(dá)進(jìn)程了一套五份下降高地中使用了這個(gè)實(shí)驗(yàn)和時(shí)間的設(shè)備會(huì)自動(dòng)觸發(fā)時(shí)壓釋放其預(yù)定的下降立場(chǎng)。細(xì)粒度( 5毫米)氧化鋁( Kadco陶瓷,新澤西州)是影響在兩個(gè)地點(diǎn)的沖擊速度下的預(yù)定;影響地點(diǎn)相距遙遠(yuǎn),以避免任何互動(dòng)的效果。直徑的壓痕提示選擇密切的大小顆粒加工中使用的超聲波馬達(dá)。 試驗(yàn)的目的是分析的動(dòng)態(tài)參數(shù)單粒子在影響和斷裂特征造成的損害。影響參數(shù)的計(jì)算
63、基于自由跌落到彈著點(diǎn)和特點(diǎn)在聯(lián)系,估計(jì)可以直接從測(cè)量或間接計(jì)算。當(dāng)圖形代表隨著時(shí)間的推移,一個(gè)單一的特點(diǎn)粒子在影響是不同的參數(shù)說明如力量,速度,或距離。了解力學(xué)的材料去除過程的意見的基礎(chǔ)上該組織進(jìn)行的幫助下,高分辨率掃描電子顯微鏡。圖 2 。a)沖擊力和速度隨著時(shí)間的推移; b )影響力和深度隨著時(shí)間的推移; c )影響速度和深度隨著時(shí)間的推移。 表2 綜述結(jié)果的影響特點(diǎn) 圖a 沖擊力和速度隨著時(shí)間的推移 圖b 影響力和深度隨著時(shí)間的推移 圖C 影響速度和深度隨著時(shí)間的推移 3 結(jié)果:沖擊力,速度和穿透深度 輸出加速度和時(shí)間的測(cè)量提供具體的
64、影響等特點(diǎn)工隊(duì)施加的影響,速度和深度滲透。結(jié)果的不同影響特點(diǎn), 列于表1 的影響是確定的工件號(hào)碼( p01 , p02和p03 ) ,和影響數(shù)量( i01 - i05 ) 。最高點(diǎn)取樣表明數(shù)據(jù)點(diǎn)數(shù)目收集采樣率萬分每秒。相對(duì)時(shí)間價(jià)值觀在計(jì)算機(jī)的幫助下,計(jì)算機(jī)軟件,其中確定該峰的位置和相對(duì)時(shí)間觸發(fā)時(shí)鐘數(shù)據(jù)存儲(chǔ)多達(dá)500點(diǎn)之后的最大深度(高峰)和高達(dá)6000點(diǎn)后的最高點(diǎn)。結(jié)束時(shí)間 秒的瞬間時(shí),壓葉片工件表面后產(chǎn)生的影響。 圖 2( a , B和C )代表的比較結(jié)果參數(shù)的影響力,速度和深度滲透在下降的速度一點(diǎn)九二米/秒。圖2A型比較沖擊速度和滲透力;在聯(lián)絡(luò)點(diǎn)的速度是最大的,并作為加快在這一點(diǎn)上是
65、零,沖擊力降到零速度降低的影響,并最終達(dá)到零上點(diǎn)壓時(shí),這一點(diǎn)對(duì)應(yīng)于即時(shí)生效時(shí)施加的壓痕的材料是最大的。這也是即時(shí)所描述的最大深度的滲透所描述在圖2b和c關(guān)于反彈的速度增加所描述的曲線之前的組合加速由于重力和材料電阻降低到零。 匯總結(jié)果的影響特點(diǎn)列于表2 。 線性增加值最大的自由落體速度有一個(gè)比例增加最多部分所經(jīng)歷的鉆石冰山期間的影響,以及 相應(yīng)增加深度。圖3描述影響最大的自由降落速度的穿透深度。深度顯示在急劇增加中間速度和相對(duì)逐步增加在低和高的速度。圖3 :影響最大的自由降落速度的穿透深度。圖4 :示意圖裂紋形態(tài)的脆性材料 。 圖5 :表面特性在沖擊速度為0.98米/秒。 4 :微
66、觀結(jié)構(gòu)分析 由于裂紋擴(kuò)展和水下裂縫主要負(fù)責(zé)材料去除,掃描電鏡技術(shù)是特別有用,它能夠讓一個(gè)生動(dòng)和更明確的代表性裂縫類型及其傳播模式方面的微觀結(jié)構(gòu)特征的材料。 在一項(xiàng)研究報(bào)告史密斯等人。關(guān)于壓痕骨折的脆性材料,中間垂直裂縫越來越表面略低于冰山的壓并包含在地下,但最終傳播到地表。橫向裂縫增長并行影響面,和宣傳的歌曲在高影響速度的特點(diǎn),這些裂縫描述 schematically圖 4 ,這顯示了截面鑒于影響地區(qū)。 SEM照片損壞的地區(qū),不同的沖擊速度介紹圖5~9。圖5顯示表面特性在7503 米下的損害的沖擊速度為0.98米/秒可以看出,分裂切和微由于撞擊力主要貢獻(xiàn)的材料去除率。一些材料去除率也可能造成脫落觀察到的粒子的存在空洞的微觀結(jié)構(gòu)。沖擊速度1.15米/秒該間存在裂紋可以看出圖6。 然而,大多數(shù)材料是從沖擊力在沖擊速度為1.5米/秒裂縫預(yù)計(jì)從變形區(qū)是顯而易見圖7。 存在這些裂紋表明橫向和中間裂紋擴(kuò)展到地表。在場(chǎng)的情況下 間微也可見,由箭頭并表示。 由于材料去除涉及塑性流動(dòng)和斷裂,它結(jié)合了壓縮和拉伸應(yīng)力,分別負(fù)責(zé)材料去除 。中位數(shù)裂紋垂直于表面和宣傳以下的變形區(qū),因壓強(qiáng)調(diào)由于撞擊力的
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